Functions of the white and topaz loci of Lucilia cuprina in the production of the eye pigment xanthommatin

The white and topaz eye color mutants of L. cuprina are defective in the production of the brown screening pigment xanthommatin. Both white and topaz mutants were found to be unable to accumulate xanthommatin precursors in the larval malpighian tubules, correlating with their reduced early pupal level of this metabolite. In addition, white mutants showed reduced rates of accumulation of kynurenine and 3-hydroxykynurenine in the adult eyes. Another mutant strain, grape, was also defective in its ability to accumulate these xanthommatin precursors in the eyes, although accumulation was normal in the larval tubules. In contrast, the topaz mutants were found to be normal in eye accumulation, although tubule accumulation was markedly abnormal. These properties of the white and topaz mutants of L. cuprina are compared with those of the white and scarlet mutants of D. melanogaster, and it seems likely that in the two species these genes are involved with the uptake or storage of xanthommatin precursors in specific tissues.This work was supported by Grant D2 75/15248 from the Australian Research Grants Committee.     

Isolation and biochemical analysis of a temperature-sensitive scarlet eye color mutant of Drosophila melanogaster

Six new EMS-induced scarlet mutants were selected. Four of these were partially pigmented, with xanthommatin levels ranging from 12% to 45% of normal. In one (st ^754ts), pigment production was temperature sensitive; the level of xanthommatin changed from less than 10% of normal at 29 C to more than 70% at 18 C. In all of the new mutants tested, the level of early pupal 3-hydroxykynurenine was as low as low as that in st ¹. Thus reduced larval accumulation of this metabolite also appears to be a characteristic feature of scarlet mutants. Temperature-pulse and temperature-shift experiments were carried out with st ^754ts to determine the temperature-sensitive period for the scarlet gene during development. The major sensitive period commenced prior to the onset of pigmentation and was over before adult emergence. Thus the initiation of xanthommatin synthesis is not brought about by the activation of the scarlet gene. In similar experiments carried out with a temperature-sensitive white mutant (w ^bl), a similar temperature-sensitive period was obtained.This work was supported by Grant D2 75/15248 from the Australian Research Grants Committee and also by Grant GB 27599 from The National Science Foundation to Professor M. M. Green.     

Xanthommatin biosynthesis in wild-type and mutant strains of the Australian sheep blowfly Lucilia cuprina

The synthesis of eye pigments has been studied in the seven eye color mutants of the Australian sheep blowfly, Lucilia cuprina. Six appear to be affected primarily in the synthesis of xanthommatin. In wild type, the onset of xanthommatin biosynthesis occurs midway through metamorphosis. Developmental patterns of accumulation of the xanthommatin precursors tryptophan, kynurenine, and 3-hydroxykynurenine have also been established for wild type. By determining the levels of these precursors in late pupae of the mutants, it has been shown that the mutant yellowish accumulates excess tryptophan and the mutant yellow accumulates excess kynurenine. The implications of these results—that yellowish lacks tryptophan oxygenase, thus failing to convert tryptophan to kynurenine, and that yellow lacks kynurenine hydroxylase (blocked in the conversion of kynurenine to 3-hydroxykynurenine)—have been confirmed. This has involved in vitro assays of tryphophan oxygenase and precursor feeding experiments. The precursor accumulation patterns are less clear for the other mutants.     

Terminal Synthesis of Xanthommatin in DROSOPHILA MELANOGASTER. III. Mutational Pleiotropy and Pigment Granule Association of Phenoxazinone Synthetase

Phenoxazinone synthetase, which catalyzes the condensation of 3-hydroxykynurenine to xanthommatin, the brown eye pigment of Drosophila, is shown to exist in association with a particle which resembles the cytologically defined Type I pigment granule. Several classical eye color mutants (v, cn, st, ltd, cd, w), including two which effect other enzymes in the xanthommatin pathway (v, cn), have low levels of phenoxazinone synthetase activity and disrupt the normal association of the enzyme with the pigment granule. A model is proposed depicting several structural and enzymatic interrelationships involved in the developmental control of xanthommatin synthesis in Drosophila.     

Terminal synthesis of xanthommatin in Drosophila melanogaster. I. Roles of phenol oxidase and substrate availability

Eye color mutants of Drosophila melanogaster are known which block the conversion of 3-hydroxykynurenine to xanthommatin. It has been proposed that this reaction depends on the presence of 3-hydroxykynurenine and a redox system maintained by phenol oxidase activity. The mutants st and ltd lack throughout development detectable amounts of 3-hydroxykynurenine or its metabolic derivatives. When the substrate is fed or injected, these mutants fail to form xanthommatin even though phenol oxidase activity is normal. The mutant cd accummulates excessive amounts of 3-hydroxykynurenine, has normal phenol oxidase activity, but is also deficient in xanthommatin formation. Mutants are also known which lack phenol oxidase activity but nevertheless form xanthommatin. It is concluded that the proposed relationship between 3-hydroxy-kynurenine and phenol oxidase activity is not sufficient to explain the in vivo synthesis and regulation of synthesis of xanthommatin in Drosophila. The bearing of these findings on the actual mode of synthesis is discussed.Supported by PHS 1029 and NSF GB-4539.     

A biochemical study of the scarlet eye-color mutant of Drosophila melanogaster

3-Hydroxykynurenine is virtually absent from st larvae but accumulates during adult development in the puparium. Over the period of adult emergence, the accumulated 3-hydroxykynurenine is excreted so that st adults contain none. Larvae of st fed on tryptophan-C ¹⁴ medium produce labeled 3-hydroxykynurenine, at a reduced rate, perhaps, compared to wild type. Xanthurenic acid levels in st pupae are similar to those in wild type. Thus the failure of st larvae to accumulate 3-hydroxykynurenine does not seem to be due either to an inability to synthesize this compound or to an excessive rate of its conversion to xanthurenic acid. Rather, it appears that the mechanism of 3-hydroxykynurenine storage during larval life is defective, so that this compound is excreted at an abnormally high rate. The inability of the pigment cells of the eyes of st to synthesize xanthommatin may result from a similar defect in their ability to take up or store 3-hydroxykynurenine.     

Xanthurenic acid 8-O-beta-D-glucoside, a novel tryptophan metabolite in eye-color mutants of Drosophila melanogaster

An unknown fluorescent metabolite has been isolated from heads of eye-color mutants of Drosophila melanogaster. Only a few mutations cause it to accumulate, viz. cardinal (cd), dark red brown (drb), Henna-recessive (Hnr), purple (pr), Punch2 (Pu2), Punch-Grape (PuGr), and scarlet (st). After purification by ion-exchange chromatography, the spectroscopic, chemical, and enzymatic analyses revealed that it is a novel quinoline derivative: xanthurenic acid 8-O-beta-D-glucoside. Feeding experiments suggest that this glucoside is synthesized from 3-hydroxykynurenine and that free xanthurenic acid is not a precursor. The results from the analysis for its occurrence in double mutants, together with the fact that xanthurenic acid 8-glucoside share the same precursor as xanthurenic acid and xanthommatin, suggest that xanthurenic acid 8-glucoside formation is closely related to the regulation of the last step in the biosynthesis of xanthommatin.     

Tryptophan metabolism during development of the stick insect,Carausius morosus Br. tissue distribution and interrelationships of metabolites of the kynurenine pathway

Summary During larval development ofCarausius morosus kynurenic acid is the major end product of tryptophan metabolism. Tryptophan and kynurenic acid have been found in the fat body, haemolymph and gut contents but only traces of kynurenine have been detected. The ommochromes ommin and xanthommatin are formed in relatively small amounts in the epidermis during larval development. 3-hydroxykynurenine was found only in the epidermis, the site of ommochrome deposition.During larval development, the amount of free tryptophan increases with body dry weight. The amount of kynurenic acid excreted also corresponds to the increase of body weight but is significantly reduced in the faeces of adults. This is related to a high tryptophan content of yolk proteins. The concentration of tryptophan in the haemolymph decreases immediately before ecdysis, whereas that in the gut increases during this time and falls sharply at the start of ecdysis.     

Oxidation of 3-hydroxykynurenine to produce xanthommatin for eye pigmentation: a major branch pathway of tryptophan catabolism during pupal development in the yellow fever mosquito, Aedes aegypti.

This study concerns the metabolic pathways of 3-hydroxykynurenine in Aedes aegypti mosquitoes during development with emphasis on its oxidation pathway to produce xanthommatin during eye pigmentation. Oxidation of tryptophan to 3-hydroxykynurenine is the major pathway of tryptophan catabolism in Aedes aegypti, but 3-hydroxykynurenine oxidizes easily under physiological conditions, which stimulate the production of reactive oxygen species. Our data show that in Aedes aegypti, the chemically reactive 3-hydroxykynurenine is converted to the chemically stable xanthurenic acid by a transaminase-catalyzed reaction during larval development, while 3-hydroxykynurenine is transported to the compound eyes for eye pigmentation during pupal development. Our data suggest that (1) the transamination pathway of 3-hydroxykynurenine is down-regulated during the pupal development, (2) 3-hydroxykynurenine produced in other body tissues is actively transported to the compound eyes during the pupal stage, (3) the compound eye is the place where ommochromes are produced, and (4) formation of ommochromes results from nonenzymatic oxidation of 3-hydroxykynurenine in the compound eyes.     

Transport defects as the physiological basis for eye color mutants of Drosophila melanogaster

Kynurenine-H ³ transport and conversion to 3-hydroxykynurenine were studied in organ culture using the Malpighian tubules and developing eyes from wild type and the eye color mutants w, st, 1td, ca, and cn of Drosophila melanogaster. Malpighian tubules from wild type have the ability to concentrate kynurenine and convert it to 3-hydroxykynurenine. The tubules from w, st, 1td, and ca are deficient in the ability to transport kynurenine, as are the eyes of the mutants w, st, and 1td. This defect in kynurenine transport provides a physiological explanation for the phenotypic properties of the mutants. The relationship of these measurements to previous observations on these eye color mutants is discussed and the transport defect hypothesis is consistently supported. We have concluded that several of the eye color mutants in Drosophila are transport mutants.     

Nonshivering thermogenesis and cold resistance during seasonal acclimatization in the Djungarian hamster

Summary The absence of juvenile hormone (JH) at the time of head capsule slippage during the molt to the fifth (final) instar of the tobacco hornworm was found to cause ommochrome (primarily dihydroxanthommatin) synthesis in the epidermis during the first two days after ecdysis. Then synthesis decreased until its transient reappearance during the wandering stage. Either JH-I (ED₅₀=8x10^–4 g) or methoprene (ED₅₀=1.4x10^–2 g) applied at this critical time during the molt prevented the first synthesis. A comparison of developmental profiles of tryptophan and its metabolites, kynurenine and 3-hydroxykynurenine, in normal and allatectomized wild type larvae showed that JH at this critical time prevented both the conversion of kynurenine to 3-hydroxykynurenine and 3-hydroxykynurenine to ommochromes. A similar study in normal and methoprene-treatedblack mutant larvae showed that only the latter conversion was inhibited by JH. The accumulation of 3-hydroxykynurenine in the epidermis of the JH-treatedblack mutant is thought to be due to the altered tryptophan metabolism in these mutants in previous instars due to lower JH levels. Neither starvation of theblack mutant nor injection of 3-hydroxykynurenine significantly affected ommochrome synthesis by the epidermis. Preliminary studies of the enzymes involved showed that JH at the critical period suppressed the later activity and/or production of kynurenine 3-hydroxylase in the wild type larva, but had little effect on the particulate ommochrome synthetase activity of the epidermis.Abbreviations CA corpora allata - JH juvenile hormone - PTTH prothoracicotropic hormone     

Ommochrome formation and kynurenine excretion in Pieris brassicae: Relation to tryptophan supply on an artificial diet

The brown-red pigment in the larval epidermis and in the testis of Pieris brassicae was identified as xanthommatin on the basis of solubility, redox behaviour, chromatography, degradation, visible and infrared spectra. In the epidermis, this pigment accumulates during the larval feeding period and disappears rapidly in the wandering stage. Larvae fed an artificial diet produce about half the amount of xanthommatin as larvae fed cabbage. This effect is caused by a lack of dietary tryptophan. Xanthommatin formation is increased by the addition of tryptophan which also increases body weight. At a tryptophan concentration of 0.2 mg per g, however, weight increase is lower than in controls and high mortality is observed. Pieris larvae excrete kynurenine in relation to dietary tryptophan. No measurable amounts are excreted in the last instar on the non-supplement diet. After feeding different quantities of tryptophan, different amounts of kynurenine are excreted only on the day following ecdysis.     

Ommochrome synthesis and kynurenic acid excretion in relation to metamorphosis and allatectomy in the stick insect, Carausius morosus Br.

End products of tryptophan metabolism in Carausius morosus are the ommochromes ommin and xanthommatin in the epidermis, and kynurenic acid in the faeces. During larval and adult life ommochromes and mainly kynurenic acid are formed. The concentration of kynurenic acid in the faeces of adult females is 2.5 times lower than in the larvae and in adult males. Allatectomy on the first day after a larval moult induces a much longer instar (10 days) than normal. After the following moult, the allatectomized animals are transformed into adultoids. The allatectomized and normal larvae produce similar amounts of kynurenic acid and ommochrome during the larval instar. Twenty days after last ecdysis, the ommochrome content in adult and adultoids is increased. In the faeces of adultoids, however, the concentration of kynurenic acid is higher than in normal female adults, but lower than in males and larvae.     

3-hydroxykynurenine as a substrate/activator for mushroom tyrosinase

3-Hydroxykynurenine is a tryptophan metabolite with an o-aminophenol structure. It is both a tyrosinase activator and a substrate, reducing the lag phase, stimulating the monophenolase activity, and being oxidized to xanthommatin. In the early stage of monophenol hydroxylation, catechol accumulation takes place, whereas 3-hydroxykynurenine is substantially unchanged and no significant amounts of the o-quinone are produced. These results suggest an activating action of 3-hydroxykynurenine toward o-hydroxylation of monophenols. 3-Hydroxykynurenine could therefore well act as a physiological device to control phenolics metabolism to catechols and quinonoids.     

Terminal synthesis of xanthommatin in drosophila melanogaster. IV. Enzymatic and nonenzymatic catalysis

Nonenzymatic and enzymatic catalysis of the oxidation of 3-hydroxykynurenine (and 3-hydroxyanthranilic acid) has been studied and characterized in Drosophila extracts, clearing up some of the confusion surrounding the synthesis of the brown eye pigment, xanthommatin. The genetic basis of the terminal steps in pigment synthesis remains obscure, since all mutants tested have full synthetase activity.     

Analysis of kynurenine transaminase activity in Drosophila by high performance liquid chromatography

A sensitive assay for kynurenine transaminase activity (E.C. 2.6.1.7) based on rapid separation of the reaction product by high performance liquid chromatography (HPLC) has been developed. Drosophila sordidula extracts have been assayed by this new method and this is the first time that kynurenine transaminase activity has been demonstrated in Drosophila. The method of assay developed can be extended to any other organism. Kynurenine and 3-hydroxykynurenine were both used as substrates, and they were transaminated to kynurenic acid and xanthruenic acid, respectively. HPLC is used to separate and quantitate these reaction products from all other components in the reaction mixture.In crude extracts from Drosophila, the reaction requires pyridoxal 5′-phosphate and an amino acid acceptor. The enzyme activity showed a maximum at 47°C and pH 8.0 with kynurenine and pyruvic acid as substrates. Transaminase activity was present in both head and body, nevertheless the specific activity was higher in the former. In bodies, pyruvic acid was the best amino acceptor whereas in heads it was α-oxoglutaric acid. The variation of kynurenine transaminase during development of D. sordidula showed, in the larval and pupal stages, activity levels practically constant and much lower than those found in the adult. This seems to suggest a preferential role of this enzyme in the metabolism of intermediates in the biosynthesis of ommochromes.     

Studies on the kynurenine adminotransferase activity in rat liver and kidney.

The kynurenine aminotransferase activity of supernatant and mitochondrial fractions obtained from rat liver and kidney was studied with L-kynurenine and L-3-hydroxykynurenine as substrates. A substrate inhibition with L-kynurenine at concentrations higher than 6-7mM was observed with all four enzyme preparations. This did not happen with L-3-hydroxykynurenine as a substrate. Moreover, the liver mitochondrial enzyme shows a Km for pyridoxal phosphate 2-4 times smaller than the other preparations when assayed with L-3-hydroxykynurenine as a substrate. Therefore, the accumulation of xanthurenic acid and not of kynurenic acid in B6 deficiency could be related both to this high activity of liver mitochondrial kynurenine aminotransferase with L-3-hydroxykynurenine, even at small concentrations of B6, and to substrate inhibition observed with L-kynurenine and not with L-3-hydroxykynurenine.     

Tryptophan metabolism in syphilis infections

Tryptophan metabolism "via kynurenine" is altered in lues: after a load of 50 mg/Kg b.w. of L-tryptophan the urinary excretion of kynurenine, 3-hydroxykynurenine and xanthurenic acid is increased, suggesting a deficiency of vitamin B6.     

Biochemical and phenotypic abnormalities in kynurenine aminotransferase II-deficient mice

Kynurenic acid (KYNA) can act as an endogenous modulator of excitatory neurotransmission and has been implicated in the pathogenesis of several neurological and psychiatric diseases. To evaluate its role in the brain, we disrupted the murine gene for kynurenine aminotransferase II (KAT II), the principal enzyme responsible for the synthesis of KYNA in the rat brain. mKat-2(-/-) mice showed no detectable KAT II mRNA or protein. Total brain KAT activity and KYNA levels were reduced during the first month but returned to normal levels thereafter. In contrast, liver KAT activity and KYNA levels in mKat-2(-/-) mice were decreased by >90% throughout life, though no hepatic abnormalities were observed histologically. KYNA-associated metabolites kynurenine, 3-hydroxykynurenine, and quinolinic acid were unchanged in the brain and liver of knockout mice. mKat-2(-/-) mice began to manifest hyperactivity and abnormal motor coordination at 2 weeks of age but were indistinguishable from wild type after 1 month of age. Golgi staining of cortical and striatal neurons revealed enlarged dendritic spines and a significant increase in spine density in 3-week-old mKat-2(-/-) mice but not in 2-month-old animals. Our results show that gene targeting of mKat-2 in mice leads to early and transitory decreases in brain KAT activity and KYNA levels with commensurate behavioral and neuropathological changes and suggest that compensatory changes or ontogenic expression of another isoform may account for the normalization of KYNA levels in the adult mKat-2(-/-) brain.